Optimization of system capacity electric power transmission systems requires a reliable power flow controller. The power flow controllers must be able to control the level of electrical voltage and active and reactive power flow without reducing the level of stability and security of the transmission system. Latest technology in the control of power flow is a Unified Power Flow Controller (UPFC). The entire transmission line parameters are impedance, voltage, and phase angle can be controlled simultaneously by the UPFC. The method used in the conventional algorithms based UPFC is still firmly with logic. These algorithms have difficulties to electric power transmission systems multimachine very dynamic, i.e. systems that are experiencing rapid changes in the electrical load from time to time. Therefore, in this study was developed based on neuro-fuzzy method is applied to the adaptive UPFC for adaptively controlling the power flow in electric power transmission systems multimachine very dynamic. In this study, three phase fault is applied to the multimachine system. The results are taken to be consideration of PI and neuro-fuzzy controllers. The PI and neuro-fuzzy controllers show nearly same results but there is a low overshoot occurred during the fault in the neuro-fuzzy controllers results. According to results that UPFC improves the system performance under the transient and the normal conditions. However, it can control the power flow in the transmission line, effectively.

Power flow; UPFC; fuzzy logic controller; neural networks; adaptive controller

. K.R. Padyar, “Power System Dynamics, Stability and Control”, John Wiley and Sons, 1996.

. L. Saribulut, M. Tumay, and I. Eker, “Performance Analysis of Fuzzy Logic Based Unified Power Flow Controller”, World Academy of Science, Engineering and Technology, 45, 2008, 320-325.

. Y. H. Song, A. T. Jons, “Flexible AC Transmission Systems (FACTS)”, IEE Power and Energy Series, 30, 1999.

. B. Lu, L. Hou, B. Li, Y. Liu, “A New Unified Power Flow Fuzzy Control Method”, Innovative Computing, Information and Control, Second International Conference, 2007, 479 – 479.

. A.T. Al-Awami, Abdel-Magid, Y.T., dan Abido, M.A., “A particle-swarm-based approach of power system stability enhancement with unified power flow controller”, International Journal of Electrical Power & Energy Systems, 29, 2007, pp. 251-259, 2007.

. S. Kannan, S. Jayaram, M. M. A. Salama, “Real and Reactive Power Coordination for a Unified Power Flow Controller”, IEEE Transactions on Power Systems, 19(3), 2004, 1454 – 1461.

. A.A. Eldamaty, Faried, S.O., Aboreshaid, S., “Damping Power System Oscillations Using A Fuzzy Logic Based Unified Power Flow Controller”, IEEE Conference Of CCECE/CCGEI, May 2005.

. T. Allaoui, Denaı, M.A., dan Bouhamida, M., “Robust control of unified power flow controller (UPFC)”, Journal of Electrical and Electronics Engineering (IU-JEEE), 7, 2007, 331-343.

. J. Guo, Crow, M.L. dan Sarangapani, J., “An improved UPFC control for oscillation damping”, IEEE Transactions on Power Systems, 14, 2009, 288-296.

. S. Hameed, Das, B., dan Pant, V., “A self-tuning fuzzy PI controller for TCSC to improve power system stability”, Electric Power Systems Research, 78, 2008, 1726-1735.

. S. Morsli, Tayeb, A., Mouloud, D., Abdelkader, C., “A robust adaptive fuzzy control of a unified power flow controller”, Turkey Journal of Elec. Eng. & Comp. Science, 20(1), 2012.

. T. Takagi, M. Sugeno, “Fuzzy Identification of Systems and Its Applications to Modeling and Control”. IEEE Transaction on Systems, Man and Sybern, 1985, 1: 116-132.

. Jang, J.S.R., "ANFIS: Adaptive-Network-based Fuzzy Inference System", IEEE Trans. Syst., Man, Cybern., 23, 1993. 665-685.